KR102439342B1 - Sensing device connected to cut-out switch - Google Patents

Abstract

The present invention relates to a fastening case for fastening a sensing unit for detecting a state of a cutout switch to the cutout switch. A fastening case according to an embodiment of the present invention is a fastening case for fastening a sensing unit for detecting a state of a cutout switch to the cutout switch, is fastened to a fuse holder of the cutout switch, and is made of an elastic material and a main body, wherein one side is provided in a tubular shape cut along the longitudinal direction, and a receiving space in which the sensing unit is accommodated.

Description

SENSING DEVICE CONNECTED TO CUT-OUT SWITCH

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic device, and more particularly, to a sensing device that is fastened to a cutout switch and detects a state of the cutout switch.

In general, the power supplied from the high voltage power line is reduced to an appropriate voltage through a transformer and supplied back to the consumer. A cut-out switch (hereinafter, COS) is mainly installed between the power line and the transformer to protect the transformer from overcurrent. The cutout switch has a structure including an upper connector, a lower connector, and a fuse holder surrounding the fuse. A fuse holder is connected between the upper connector and the lower connector. The upper connector is connected to the branch point of the high voltage power line, and the lower connector is connected to the primary side of the transformer.

The maintenance and management method of a power facility equipped with a cutout switch is a method in which an operator directly climbs on an electric pole and visually checks or uses test equipment. However, since the operation requires access to the cutout switch mounted between the special high-voltage line and the pole transformer, the operator is always exposed to the risk of electric shock. In addition, in order to monitor the occurrence of a failure or defect of the cutout switch, an administrator must periodically maintain and manage it manually. However, there is a problem in that it is difficult for an operator to directly check the cutout switch in a bad weather situation, and when a failure or malfunction of the cutout switch occurs, it is not possible to deal with the cutout switch in real time.

In addition, at present, power equipment equipped with a cutout switch, including a transformer, is repaired only when a failure occurs. Therefore, it is difficult to prevent failures and provide high-quality power services through preventive maintenance by detecting in advance the signs of deterioration or failure warnings of power facilities equipped with cutout switches.

The present invention is to solve the above problems, and an object of the present invention is to provide a sensing device that monitors the state of a cutout switch in real time to detect failures and failure notice symptoms to provide ease of maintenance and repair of power equipment it is to do

It is also an object of the present invention to provide a sensing device that can be easily detached from a cutout switch.

The present invention provides a sensing device that is fastened to a cutout switch. A sensing device according to an embodiment of the present invention includes: a sensing unit sensing a state of a cutout switch; and a fastening case for fastening the sensing unit to the cutout switch, wherein the fastening case includes a main body fastened to a fuse holder of the cutout switch and made of an elastic material, the main body having one side It is provided in a tubular shape cut along the longitudinal direction, and includes an accommodation space in which the sensing unit is accommodated.

The accommodating space may be provided in a shape recessed inward from the outer surface of the main body, and the fastening case may further include a cover covering the open surface of the accommodating space.

The cover may be provided in a tubular shape that is provided of an elastic material, one side is cut along the longitudinal direction, and the outer and inner surfaces of the main body can be engaged.

A fastening protrusion protruding in a direction in which the inner surface of the cover is viewed may be formed on the inner surface of the cover, and a fastening groove engaged with the fastening protrusion may be formed on the outer surface of the body.

The sensing unit may include: a sensor unit sensing an acceleration or sound of the fuse holder and outputting an acceleration signal and an audio signal; a control unit configured to detect a level of the acceleration signal or the audio signal to determine a failure state or a failure notice state of the cutout switch; a wireless communication unit for transmitting an event signal corresponding to the failure state or the failure notice state under the control of the controller; and a power supply unit for supplying power to the sensor unit, the control unit, and the wireless communication unit by using the electromotive force induced from the fuse holder, wherein the control unit compares the level of the acceleration signal or the audio signal with a threshold value. The replacement cycle of the cutout switch is determined, and the power supply unit may include a supercap for temporarily storing the power.

The sensing device according to an embodiment of the present invention is to provide easiness of maintenance and repair of power equipment by monitoring a state of a cutout switch in real time to detect failures and failure warning symptoms.

In addition, the sensing device according to an embodiment of the present invention may be easily detached from the cutout switch.

1 is a view showing a cutout switch to which a sensing device of the present invention is fastened.
2 is a perspective view illustrating a sensing device according to an embodiment of the present invention.
3 is an exploded perspective view of the sensing device of FIG. 2 ;
4 is a cross-sectional view illustrating a state in which the sensing device of FIG. 2 is cut in a direction perpendicular to the longitudinal direction.
FIG. 5 is a block diagram showing an example of the configuration of the sensing unit shown in FIG. 3 .
6A and 6B are diagrams exemplarily illustrating an operation of the sensor unit shown in FIG. 5 .
7 is a flowchart exemplarily illustrating a fuse holder monitoring operation of the sensing unit of FIG. 5 .
8 is a flowchart illustrating another embodiment of a monitoring operation of the sensing unit of FIG. 5 .
9 is a flowchart illustrating another embodiment of a monitoring operation of the sensing unit of FIG. 5 .
FIG. 10 is a diagram briefly showing features of software of the control unit shown in FIG. 5 .
11 is a block diagram exemplarily illustrating a power supply unit illustrated in FIG. 5 .
12 is a diagram exemplarily showing an event detection and transmission method by sensing units of the present invention.
13 is a flowchart exemplarily illustrating a monitoring operation of the master sensing unit of FIG. 12 .

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In adding reference numerals to components of each drawing, the same components may have the same reference numerals as much as possible even though they are indicated in different drawings. In addition, in describing the present invention, when it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description may be omitted.

1 is a view showing a cutout switch to which a sensing device of the present invention is fastened. 2 is a perspective view illustrating a sensing device according to an embodiment of the present invention. 3 is an exploded perspective view of the sensing device of FIG. 2 ; 4 is a cross-sectional view illustrating a state in which the sensing device of FIG. 2 is cut in a direction perpendicular to the longitudinal direction.

1 to 4 , the cutout switch 10 of the sensing device 100 is fastened to the fuse holder 12 and detects the state of the cutout switch 10 . According to an embodiment, the sensing device 100 may include a sensing unit 110 and a fastening case 120 .

The detection unit 110 detects the state of the cutout switch 10 . The sensing unit 110 may be embedded in the fastening case 120 detachable from the fuse holder 12 . The sensing unit 110 may be mounted on the fuse holder 12 while being inserted into the fastening case 120 . The sensing unit 110 may be provided in the form of a module or a chip in which elements are embedded in a PCB substrate.

The sensing unit 110 basically includes an acceleration sensor and an acoustic sensor. When the fuse holder 12 is removed from the cutout switch 10, or a problem such as arc generation or arc extinguishing occurs, the detection unit 110 may detect a failure event through an acoustic sensor and an acceleration sensor. .

The sensing unit 110 may generate power by using an electromagnetic induction phenomenon of a fuse located inside the fuse holder 12 . And it may include a transceiver for wireless communication for detecting the occurrence of an event or for periodically transmitting the state of the cutout switch 10 . The sensing unit 110 may be mounted to be located in the center of the fuse holder 12 .

The cutout switch 10 may be fixed to an electric pole or a support by an attachment bracket 17 . A support insulator 13 as an insulator made of an insulator is attached to one end of the attachment bracket 17 . A power-side terminal 14 and a load-side terminal 15 are provided at both ends of the support insulator 13 , respectively. A lead wire drawn in from a power line is connected to the power-side terminal 14 , and a lead wire drawn out from a pole-phase transformer is connected to the load-side terminal 15 .

A fuse holder 12 is provided between the power supply terminal 14 and the load terminal 15 . The fuse holder 12 has a fuse (not shown) installed therein, and both ends of the fuse are electrically connected to the power-side terminal 14 and the load-side terminal 15 . The lower end of the fuse holder 12 is rotatably installed on the bracket 16 , and the bracket 16 is connected to the load-side terminal 15 .

According to an embodiment, the detection unit 110 measures the sound and acceleration of the fuse holder 12 of the cutout switch 10 and detects a failure or a failure notice symptom of the cutout switch 10 using the measurement result. can be detected. When the detection unit 110 detects a failure or a failure warning symptom, the detected acceleration or sound data may be transmitted to the central data management device through wireless communication. Accordingly, since the manager can determine whether a failure or replacement cycle occurs without directly accessing the cutout switch 10 , it is possible to reduce the risk of maintenance and repair of the power equipment.

The fastening case 120 fastens the sensing unit 110 to the cutout switch 10 . The fastening case 120 may be detachably provided to the fuse holder 12 of the cutout switch 10 . According to an embodiment, the fastening case 120 includes a body 121 and a cover 122 .

The body 121 is detachably fastened to the fuse holder 12 of the cutout switch 10 . The body 121 may be made of a material having elasticity. For example, the body 121 may be made of a hard synthetic resin material having elasticity, such as polyester. Alternatively, the body 121 may be provided as a sponge structure made of a synthetic resin material such as polyester. The body 121 may maintain a shape other than the above-mentioned materials and may be provided with various materials having sufficient elasticity.

According to an embodiment, the main body 121 is provided in a tubular shape in which one side is cut along the longitudinal direction. Therefore, after applying an external force to the main body 121 to place the inner surface 1211 surrounding the fuse holder 12 with the cut ends spread apart, the applied force is released so that the inner surface 1211 is connected to the fuse holder ( It can be mounted on the fuse holder 12 by being in close contact with the outer surface of the 12). In addition, the main body 121 may be separated from the fuse holder 12 in a state where both ends of the cut end are spread by applying an external force to the main body 121 fastened to the fuse holder 12 as described above. When viewed along the longitudinal direction of the main body 121, the width and shape of the inner space formed by the inner surface 1211 of the main body 121 is the outer surface when viewed along the longitudinal direction of the fuse holder 12 to be mounted. may be provided corresponding to the width and shape of

Both ends of the cut portion of the main body 121 are connected to each other in a state where no external force is applied to the main body 121 so that the cut portions for fastening to the fuse holder 12 can be spread apart at sufficient intervals with less force. It may be provided to be spaced apart. However, the spacing between both ends of the cut portion of the main body 121 is provided within a size sufficient to enclose the fuse holder 12 so that the main body 121 can maintain a state attached to the fuse holder 12 . . For example, when the fuse holder 12 is provided in a cylindrical shape, an interval at which both ends of the cut portion of the body 121 are spaced apart is greater than or equal to the radius of the fuse holder 12 and smaller than or equal to the diameter of the fuse holder 12 . can be provided as

The body 121 includes an accommodation space 1213 in which the sensing unit 110 is accommodated. According to an embodiment, the receiving space 1213 may be provided in a shape that is indented from the outer surface 1212 of the main body 121 . According to an embodiment, the accommodation space 1213 may be provided in a central area of the body 121 . In addition, in order to form an accommodation space 1213 of a sufficient size in the main body 121 , the main body 121 may be provided in a shape that becomes thicker from both ends of the cut portion toward the central region.

The cover 122 covers the open surface of the storage space 1213 formed in the fastening case 120 . According to an embodiment, one side of the cover 122 is cut along the longitudinal direction, and the outer surface 1212 and the inner surface 1221 of the main body 121 may be provided in a tubular shape that can be engaged. According to an embodiment, in a state in which the cover 122 is fastened to the main body 121 to cover the open surface of the receiving space 1213 of the main body 121 , the cut portion of the cover 122 is the main body 121 . ) may be provided to face the same direction as the cut part. The cover 122 may be provided with a material having elasticity. For example, the cover 122 may be provided with the same material as the body 121 . Compared to the body 121 , the cover 122 may have a uniform overall thickness between the inner surface 1221 and the outer surface 1222 .

According to an embodiment, a fastening protrusion 1223 protruding in a direction in which the inner surface 1221 of the cover 122 is viewed may be formed on the inner surface 1221 of the cover 122 . In addition, a fastening groove 1214 engaged with the fastening protrusion 1223 may be formed on the outer surface 1212 of the main body 121 . For example, the fastening protrusions 1223 may be provided in regions adjacent to both ends of the cut portion of the inner surface 1221 of the cover 122 , respectively. In addition, the fastening grooves 1214 may be provided in regions adjacent to both ends of the cut portion of the outer surface 1212 of the main body 121 to correspond to the fastening protrusions 1223 , respectively. As described above, by providing the fastening protrusion 1223 and the fastening groove 1214 , the cover 122 may more stably maintain a fastened state to surround the outer surface 1212 of the main body 121 .

The cover 122 may be detached from the main body 121 in the same or similar manner to the above-described method of fastening the main body 121 to the fuse holder 12 . The cover 122 may be coupled to the body 121 after the body 121 is coupled to the fuse holder 12 , and may be separated from the body 121 before the body 121 is separated from the fuse holder 12 . . On the other hand, when the main body 121 and the cover 122 are made of a sufficiently flexible material, the main body 121 may be detachably attached to the fuse holder 12 while the cover 122 is fastened. In this case, the cover 122 may be detachably attached to the body 121 in such a way that the main body 121 is inserted into the cover 122 in the longitudinal direction and separated along the longitudinal direction.

As described above, in the fastening case 120 according to an embodiment of the present invention, the main body 121 and the cover 122 are provided with an elastic material, and one side is provided in the shape of a tube cut in the longitudinal direction, so that the fuse It can be easily detached from the holder 12 .

FIG. 5 is a block diagram showing an example of the configuration of the sensing unit 110 shown in FIG. 3 . Referring to FIG. 5 , the sensing unit 110 may include a sensor unit 111 , a control unit 113 , a power supply unit 115 , a wireless communication unit 117 , and an antenna 119 .

The sensor unit 111 senses detachment of the fuse holder 12 , vibration, and noise. The sensor unit 111 transmits the sensing signals AS and SS to the control unit 113 . The sensor unit 111 may include an acceleration sensor 112 and an acoustic sensor 114 . The acceleration sensor 112 may sense a movement or vibration such as the detachment of the fuse holder 12 . The acceleration sensing signal AS sensed by the acceleration sensor 112 is transmitted to the controller 113 . The acceleration sensor 112 may be implemented as, for example, a digital gyroscope that measures acceleration with respect to each of a plurality of axes. The acoustic sensor 114 senses the sound generated by the fuse holder 12 and transmits it to the controller 113 . The acoustic sensor 114 may convert sound pressure into an electrical signal. The acoustic sensor 114 may transmit the audio sensing signal SS converted into an electrical signal to the controller 113 . The acoustic sensor 114 may be implemented as, for example, a Micro-Electro Mechanical Systems (MEMS) microphone, but the present invention is not limited thereto.

The controller 113 may determine whether a failure of the fuse holder 12 or failure of the fuse holder 12 is predicted by referring to the sensing signals AS and SS provided from the sensor unit 111 . The controller 113 may determine whether the level of at least one of the sensing signals AS and SS corresponds to a failure or a failure prediction value. If the level of at least one of the sensing signals AS and SS corresponds to the failure or the predicted failure value, the control unit 113 generates an event signal and transmits it to the central data management device through the wireless communication unit 117 . . When configured with a processor such as a microcontroller unit (MCU), the controller 113 may be driven by firmware, and the firmware may be downloaded and updated if necessary.

The power supply unit 115 provides power for driving the sensor unit 111 , the control unit 113 , the wireless communication unit 117 , and the antenna 119 constituting the sensing unit 110 . The power supply unit 115 may receive wireless power (WP) and convert it into an electrical energy form. For example, the power supply unit 115 may generate power in the form of obtaining an induced electromotive force through time-varying electromagnetic waves generated from a fuse lead wire inside the fuse holder 12 . In addition, the power supply unit 115 may further include an auxiliary power source for charging power generated from wireless power. For example, power generated by wireless power may be stored in an auxiliary power supply such as a Super-Cap. When an event such as the detachment of the fuse holder 12 occurs, the electromotive force induced through the fuse lead wire is removed, but the sensing unit 110 can operate normally for a certain period of time by the power stored in the supercap.

The wireless communication unit 117 transmits and receives a wireless signal through the antenna 119 . The wireless communication unit 117 may transmit an event signal or a status signal provided from the control unit 113 to the central data management apparatus. In addition, the wireless communication unit 117 may receive an event signal or a status signal transmitted from another sensing unit in a short distance. The wireless communication unit 117 may communicate through an Internet of Things (IoT) protocol implemented by Zigbee, Bluetooth, or Wi-Fi.

In the above, the configurations and functions of the sensing unit 110 of the present invention have been briefly described. However, the configuration or function of the sensing unit 110 of the present invention is not limited thereto. For example, by mounting an artificial intelligence (AI) program in the processor constituting the control unit 113 , higher reliability may be realized through machine learning for a failure event or a failure notice event.

6A and 6B are diagrams exemplarily illustrating the operation of the sensor unit 111 illustrated in FIG. 5 . 6A shows an acceleration waveform measured by the acceleration sensor 112 (refer to FIG. 2 ) when a failure event occurs. On the other hand, FIG. 6B shows an audio waveform when a failure event of the acoustic sensor 114 (refer to FIG. 2 ) occurs.

Referring to FIG. 6A , when the cutout switch COS 100 is removed, the acceleration change in each of the three axes (X, Y, Z) directions is illustrated by the acceleration sensor 112 . At the moment when the fuse holder 12 of the cutout switch 10 is detached and spaced apart from the power-side terminal 14 , a change in acceleration occurs due to the movement of the detection sensor 110 attached to the fuse holder 12 . That is, at the point of disconnection of the cutout switch 10 (assumed to be T1 ), the fuse holder 12 will disengage from the upper contact point and rotate on the lower bracket 16 . At this time, from the moment the fuse holder 12 is detached from the upper contact point, vibration or acceleration in each of the three axes (X, Y, Z) directions will increase. Then, the vibration is attenuated for a certain period of time until the fuse holder 12 is stopped by the bracket 16 . This phenomenon is measured by the acceleration sensor 112 and transmitted to the controller 113 as acceleration sensing signals ASX, ASY, and ASZ. Here, the measurement of the acceleration with respect to the three axes (X, Y, and Z) has been described as an example, but this is only an example and the measurement of the acceleration with respect to one or more axes is possible.

Referring to FIG. 6B , an audio waveform when the cutout switch 10 is dropped is shown. An impact sound generated when the fuse holder 12 of the cutout switch 10 is disconnected from the upper fixing part and cut off from the power supply terminal 14 will be measured by the acoustic sensor 114 . As mentioned in FIG. 3A , at the time point T1 of the cutout switch 10 disengagement, the fuse holder 12 will disengage from the upper contact point and rotate around the lower bracket 16 as an axis. A peak SSp of the audio sensing signal SS will be observed at the moment T1 when the fuse holder 12 is detached from the upper contact point. The control unit 113 may detect the level of the audio sensing signal SS and, when exceeding the threshold TH2, determine it as a failure or a failure notice symptom, and transmit this state to the central data management device.

In the above, the acceleration and acoustic waveforms measured by the sensor unit 111 when the cutout switch COS is removed have been briefly described. However, the sensor unit 111 of the present invention may sense various failures or symptoms according to the arrival of replacement lifespan other than the dropout of the cutout switch COS through measurement of acceleration or sound. In addition, the sensor unit 111 may further include a humidity sensor, a magnetic sensor, and various sensors for higher reliability.

7 is a flowchart exemplarily illustrating a fuse holder monitoring operation of the sensing unit 110 of FIG. 5 . Referring to FIG. 7 , the control unit 113 of the sensing unit 110 (see FIG. 2 ) determines a failure state or a failure notice state according to the levels of sensing signals AS and SS provided from the sensor unit 111 . can

In step S110 , the controller 113 detects the acceleration sensing signal AS and the audio sensing signal SS provided from the acceleration sensor 112 and the acoustic sensor 114 . The controller 113 may detect the level of the acceleration sensing signal AS and the audio sensing signal SS to determine whether the cutout switch 10 is a failure or a failure warning symptom.

In step S120 , the controller 113 determines whether the level of the acceleration sensing signal AS exceeds a first threshold TH1 . Here, the first threshold TH1 may be an acceleration value input in advance by an administrator. For example, the first threshold TH1 may be a reference value obtained through repeated experiments or statistics. If the level of the acceleration sensing signal AS is higher than the first threshold TH1 (in the YES direction), the procedure moves to step S130. On the other hand, when the level of the acceleration sensing signal AS is not higher than the first threshold TH1 (in the NO direction), the procedure may return to step S110 . Here, the acceleration sensing signal AS may correspond to any one of the plurality of axes or may be a value obtained by combining acceleration values of each of the plurality of axes.

In step S130 , the controller 113 determines whether the level of the audio sensing signal SS exceeds a second threshold TH2 . Here, the second threshold TH2 may be a value of an audio signal previously input by the manager. For example, the second threshold TH2 may be a value determined by applying an experiment or statistics. If the level of the audio sensing signal SS is higher than the second threshold TH2 (in the YES direction), the procedure moves to step S140. On the other hand, when the level of the audio sensing signal SS is not higher than the second threshold TH2 (in the NO direction), the procedure may return to step S110.

In step S140 , the controller 113 determines that the cutout switch is faulty as the levels of the acceleration sensing signal AS and the audio sensing signal SS both exceed the predetermined thresholds TH1 and TH2. The controller 113 will store the determined failure event and the level of the acceleration sensing signal AS and the audio sensing signal SS in a memory provided therein.

In step S150 , the controller 113 transmits the level of the acceleration sensing signal AS and the audio sensing signal SS corresponding to the occurrence of the failure event to the central data management device. The control unit 113 transmits the failure event occurrence and the level of the sensed signals through the wireless communication unit 117 (refer to FIG. 2 ) to determine whether the cutout switch 10 on which the detection unit 110 is mounted has a failure and failure determination. The underlying data is provided to the central data management unit.

In the above, the monitoring operation of a failure or failure warning symptom of the detection unit 110 according to an embodiment of the present invention has been briefly described. Here, it has been described that the threshold values TH1 and TH2 of the acceleration sensing signal AS and the audio sensing signal SS for determining whether a failure or a failure warning symptom is provided at one level, respectively. However, it will be well understood that the thresholds TH1 and TH2 are provided at a plurality of levels, respectively, and may be implemented to detect events of more detailed symptoms.

8 is a flowchart illustrating another embodiment of a monitoring operation of the sensing unit 110 of FIG. 5 . Referring to FIG. 8 , the controller 113 may determine a failure event even when at least one of the acceleration sensing signal AS and the audio sensing signal SS exceeds a threshold value.

In step S210 , the controller 113 detects the acceleration sensing signal AS and the audio sensing signal SS provided from the acceleration sensor 112 and the acoustic sensor 114 .

In step S220 , the controller 113 determines whether the level of the acceleration sensing signal AS exceeds a first threshold TH1 . If the level of the acceleration sensing signal AS is higher than the first threshold TH1 (in the YES direction), the procedure moves to step S240. On the other hand, if the level of the acceleration sensing signal AS is not higher than the first threshold TH1 (in the NO direction), the procedure moves to step S230.

In step S230 , the controller 113 determines whether the level of the audio sensing signal SS exceeds the second threshold TH2 . If the level of the audio sensing signal SS is higher than the second threshold TH2 (in the YES direction), the procedure moves to step S240. On the other hand, when the level of the audio sensing signal SS is not higher than the second threshold TH2 (in the NO direction), the procedure may return to step S210 .

In step S240 , the controller 113 determines that the cutout switch has failed as the level of at least one of the acceleration sensing signal AS and the audio sensing signal SS exceeds the thresholds TH1 and TH2 . The controller 113 will store the determined failure event and the level of the acceleration sensing signal AS and the audio sensing signal SS in a memory provided therein.

In step S250 , the controller 113 transmits the level of the acceleration sensing signal AS and the audio sensing signal SS corresponding to the occurrence of the failure event to the central data management device. The control unit 113 transmits the failure event occurrence and the level of the sensed signals through the wireless communication unit 117 (refer to FIG. 2 ) to determine whether the cutout switch 10 on which the detection unit 110 is mounted has a failure and failure determination. The underlying data is provided to the central data management unit.

In the above, the monitoring operation of the failure or failure warning symptom of the detection unit 110 according to another embodiment of the present invention has been briefly described. Here, the controller 113 may determine a failure event when any one of the acceleration sensing signal AS and the audio sensing signal SS exceeds a threshold value.

9 is a flowchart illustrating another embodiment of a monitoring operation of the sensing unit 110 of FIG. 5 . Referring to FIG. 9 , the controller 113 may process the levels of the acceleration sensing signal AS and the audio sensing signal SS through artificial intelligence (AI) processing. The control unit 113 may use artificial intelligence (AI) to determine a failure or a failure notice, and also determine whether a replacement period has been reached.

In step S310 , the controller 113 detects the acceleration sensing signal AS and the audio sensing signal SS provided from the acceleration sensor 112 and the acoustic sensor 114 .

In step S320 , the controller 113 processes the levels of the acceleration sensing signal AS and the audio sensing signal SS through artificial intelligence (AI) operation. For example, the level of the acceleration sensing signal AS and the audio sensing signal SS may be processed and processed with an artificial intelligence algorithm such as unsupervised learning to classify a failure or symptom of the cutout switch. Alternatively, a machine learning technique using a convolutional neural network (CNN) to input an acceleration sensing signal AS and an audio sensing signal SS and outputting a state of a cutout switch may be used. For this processing, the control unit 113 may further include a processor (eg, NPU) entirely in charge of artificial intelligence (AI) calculations.

In step S330, the control unit 113 performs an operation branch according to the processing result of the artificial intelligence (AI) operation. As a result of artificial intelligence (AI) calculation, when it is determined that a failure or replacement cycle has been reached (YES direction), the procedure moves to step S340. On the other hand, if it is determined as a result of the artificial intelligence (AI) operation that the failure or replacement period has not been reached (in the NO direction), the procedure returns to step S310.

In step S340 , the control unit 113 determines that a failure or replacement cycle of the cutout switch 10 has been reached. In addition, the controller 113 will store, in the memory, determination data related to reaching the determined failure or replacement cycle, and data on the levels of the acceleration sensing signal AS and the audio sensing signal SS corresponding thereto.

In step S350 , the controller 113 transmits the levels of the acceleration sensing signal AS and the audio sensing signal SS corresponding to the failure or replacement cycle event to the central data management device.

In the above, some embodiments related to the operation of the controller 113 of the present invention have been described. However, it will be well understood that the present invention is not limited to the illustrated embodiment, and that various modifications from the described examples are possible.

FIG. 10 is a diagram briefly showing the features of software of the control unit 113 shown in FIG. 5 . Referring to FIG. 10 , the software 230 executed by the control unit 113 includes a user application 237 for performing the function of the sensing unit 113 of the present invention, an acceleration sensor 112 and an acoustic sensor 114 . Drivers 231 and 233 for driving are included.

The user application 237 analyzes the level or characteristics of the sensing signals AS and SS provided from the acceleration sensor 112 and the acoustic sensor 114 to detect an event such as failure or failure notice of the cutout switch 10 . identify The user application 237 may be provided as software driven by the controller 113 implemented as a micro-controller unit (MCU). In addition, the user application 237 may include a sensor queue 239 for temporarily storing a queue of sensing signals provided by the acceleration sensor driver 231 and the acoustic sensor driver 233 .

The acceleration sensor driver 231 provides an interface between the acceleration sensor 112 implemented in hardware and the controller 113 . The acceleration sensor driver 231 may convert a command generated by the controller 113 into a signal for controlling the acceleration sensor 112 . The acoustic sensor driver 233 may convert a command generated by the controller 113 into a signal for controlling the acoustic sensor 114 .

The user application 237 temporarily stores the sensing signals AS and SS provided from the acceleration sensor 112 and the acoustic sensor 114 in the sensor queue 239 . And the user application 237 determines the state of the cutout switch 10 according to the processing procedure of FIGS. 5 to 7 for the queue stored in the sensor queue 239 . According to the status determination, the user application 237 writes the datalog 235, which is then stored in the memory 116. When the user application 237 determines that an event has occurred, the data stored in the memory 116 will be transmitted to the central data management device. Here, the memory 116 may be implemented as a nonvolatile memory device such as a flash memory or a memory card.

11 is a block diagram exemplarily illustrating the power supply unit 115 shown in FIG. 5 . Referring to FIG. 11 , the power supply unit 115 may include a coil 115a , a rectifier circuit 115b , and a supercap 115c .

The coil 115a may be provided to obtain an induced electromotive force from a time-varying electromagnetic field generated by an alternating current flowing through the fuse. An alternating current will flow through both ends of the coil 115a by the induced electromotive force generated by the coil 115a.

The rectifier circuit 115b converts an AC voltage generated by the AC current induced in the coil into a DC voltage. The rectifier circuit 115b may be implemented as, for example, a full-wave rectifier circuit in which a diode is connected as a bridge circuit or a half-wave rectifier circuit that rectifies only one side voltage of an AC waveform.

The supercap 115c may accumulate power output from the rectifier circuit 115b. For example, the supercap 115c may include one or more capacitors that charge a charge. The sensing unit 110 processes the sensing signals provided from the acceleration sensor 112 and the acoustic sensor 114 even after the cutout switch is dropped and the electromotive force induced in the coil is lost, and the result is transmitted through the wireless communication unit 117 . should be able to transmit. Therefore, the supercap 115c must be able to store an amount of power capable of processing data even after the wireless power is cut off and transmitting the processing result to the central data management device. Accordingly, the supercap 115c may be formed of a capacitor having high stability. For example, the supercap 115c may be formed of at least one of elements such as an electrolytic capacitor, a film capacitor, a tantalum capacitor, and a ceramic capacitor (eg, a multi-layer ceramic capacitor (MLCC)). However, the supercap ( The types of 115c are not limited to those described above, and it will be understood that the supercap 115c may be replaced with various auxiliary power devices capable of temporarily storing power.

In the above, an exemplary configuration of the power supply unit 115 of the present invention has been briefly described. However, the configuration method of the power supply unit 115 may be variously changed according to the size, required power or characteristics of the sensing unit 110 .

12 is a diagram exemplarily showing an event detection and transmission method by sensing units of the present invention. Referring to FIG. 12 , a plurality of sensing units 312 , 314 , 322 , 324 , 332 , and 334 are fuse holders of cutout switches connected to transformers 311 , 313 , 321 , 323 , 331 , 333 , respectively. will be mounted on For example, sensing units will be installed in each of the cutout switches that protect the three-phase transformers installed in each of the plurality of utility poles (310, 320, 330). Here, although the consumer 340 of the power is shown as one, it will be well understood that different consumers may be connected to each of the telephone poles 310 , 320 , 330 .

The plurality of sensing units 312 , 314 , 322 , 324 , 332 , 334 may communicate with a master in a slave relationship and transmit a failure or failure notice event. Exemplarily, among the plurality of sensing units 312, 314, 322, 324, 332, and 334, the sensing unit 324 installed on the telephone pole 320 operates as a master, and the remaining sensing units 312, 314 , 322 , 332 , and 334 may operate as slaves. The slave detection units 312 , 314 , 322 , 332 , and 334 periodically inform the master detection unit 324 of a failure or abnormality of the cutout switch. In addition, the master sensing unit 324 will transmit status information about the competent sensing units 312 , 314 , 322 , 324 , 332 , 334 including itself to the central data management device 350 . This communication is possible because each of the plurality of sensing units 312, 314, 322, 324, 332, 334 may be connected through a communication protocol (eg, IoT protocol, RF communication protocol, LoRa communication protocol, etc.) Because.

In particular, when any one of the plurality of detection units 312 , 314 , 322 , 324 , 332 , and 334 detects a failure or a failure notice event, the corresponding detection unit notifies the master detection unit 324 of the occurrence of the event. If the detection unit 312 detects that the fuse holder is detached, the detection unit 312 will transmit an event signal to the master detection unit 324 together with an identifier (ID) assigned to the detection unit 312 . Then, the master detection unit 324 will transmit the identifier (ID) of the failure detection unit 312 to the central data management device 350 in real time with the occurrence of the corresponding event.

The above-described master-slave relationship may also be established between the sensing units installed on each phase of the three-phase line. That is, when a failure or failure notice event is detected in any one of the detection units installed on the three-phase line, the corresponding detection unit sends an event signal along with an identifier (ID) using a communication protocol to the master detection unit of the three-phase line. Alternatively, the data may be transmitted to the data management device 350 .

13 is a flowchart exemplarily illustrating a monitoring operation of the master sensing unit 324 of FIG. 12 . Referring to FIG. 13 , the master sensing unit 324 may periodically receive status signals from itself and the slave sensing units 312 , 314 , 322 , 332 , and 334 . And when a failure or a failure notice event occurs, the master detection unit 324 may transmit the detected failure data together with an identifier (ID) corresponding to the cutout switch in which the failure occurs to the central data management apparatus in real time.

In step S410 , the master sensing unit 324 may receive status information from itself and the slave sensing units 312 , 314 , 322 , 332 , 334 including itself. The plurality of detection units 312 , 314 , 322 , 324 , 332 , and 334 periodically monitor the acceleration sensing signal AS and the audio sensing signal SS to determine whether there is a failure or abnormality, and detect the result of the master to unit 324 .

In step S420 , the master detection unit 324 analyzes status information from itself and the slave detection units 312 , 314 , 322 , 332 , 334 to check whether a failure or failure notice event exists. If an event corresponding to a failure or a failure notice does not exist among the plurality of detection units 312, 314, 322, 324, 332, and 334 (in the NO direction), the procedure moves to step S410. Thereafter, monitoring of the plurality of sensing units 312 , 314 , 322 , 324 , 332 , 334 will continue. On the other hand, if it is determined that there is an event corresponding to a failure or a failure notice from at least one of the plurality of detection units 312, 314, 322, 324, 332, 334 (YES direction), the procedure moves to step S430 .

In step S430 , the master detection unit 324 transmits status information (audio and acceleration information) together with an identifier (ID) of the detection unit in which a failure or failure notice event has occurred to the central data management device.

In the above, a communication method and an event transmission method between the plurality of sensing units 312 , 314 , 322 , 324 , 332 , and 334 have been briefly described. However, the above-described master/slave relationship of the plurality of sensing units 312 , 314 , 322 , 324 , 332 , and 334 is merely an example. That is, wireless communication between the plurality of sensing units 312 , 314 , 322 , 324 , 332 , 334 or between the sensing unit and the central data management device is a chain method or short-range communication such as Bluetooth or Wi-Fi, or It will be appreciated that it may also be implemented through mobile communication.

The above are specific embodiments for carrying out the present invention. The present invention will include not only the above-described embodiments, but also simple design changes or easily changeable embodiments. In addition, the present invention will include techniques that can be easily modified and implemented using the embodiments. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be defined by the claims described below as well as the claims and equivalents of the present invention.

10: cutout switch 12: fuse holder
100: detection device 110: detection unit
111: sensor unit 113: control unit
115: power unit 117: wireless communication unit
120: fastening case 121: body
122: cover 1213: storage space
1214: fastening groove 1223: fastening protrusion

Claims (5)

A sensing device coupled to a cutout switch, the sensing device comprising:
a detection unit for detecting the state of the cutout switch; and
a fastening case for fastening the sensing unit to the cutout switch;
The fastening case is
and a main body fastened to the fuse holder of the cutout switch and made of an elastic material;
The main body is provided in a tubular shape, one side of which is cut along the longitudinal direction, and both ends of the cut are greater than or equal to a radius of the fuse holder, and are spaced apart from each other at intervals smaller than the diameter of the fuse holder to be detachable from the fuse holder. A sensing device including a receiving space mounted and fixed to the sensor and accommodating the sensing unit therein. The method of claim 1,
The receiving space is provided in a shape recessed inward from the outer surface of the main body,
The fastening case may further include a cover covering the open surface of the storage space. 3. The method of claim 2,
The cover is provided with an elastic material, one side is cut along the longitudinal direction, and the sensing device is provided in a tubular shape in which the outer and inner surfaces of the main body can be engaged. 4. The method of claim 3,
A fastening protrusion is formed on the inner surface of the cover to protrude in a direction in which the inner surface of the cover is viewed,
A sensing device in which a fastening groove engaged with the fastening protrusion is formed on an outer surface of the main body. The method of claim 1,
The sensing unit is
a sensor unit sensing an acceleration or sound of the fuse holder and outputting an acceleration signal and an audio signal;
a control unit configured to detect a level of the acceleration signal or the audio signal to determine a failure state or a failure notice state of the cutout switch;
a wireless communication unit for transmitting an event signal corresponding to the failure state or the failure notice state under the control of the controller; and
A power supply unit for providing power to the sensor unit, the control unit, and the wireless communication unit by using the electromotive force induced from the fuse holder,
The control unit determines a replacement cycle of the cutout switch by comparing the level of the acceleration signal or the audio signal with a threshold,
and the power supply unit includes a supercap for temporarily storing the power.

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